CN101194110B

CN101194110B - Rotary ring bearing structure

Info

Publication number: CN101194110B
Application number: CN200580049970XA
Authority: CN
Inventors: 吉田孝文; 田北胜彦; 三宅寿生; 柴田昌明; 中岛圭太
Original assignee: Mitsubishi Heavy Industries Ltd
Current assignee: Mitsubishi Heavy Industries Ltd
Priority date: 2005-05-31
Filing date: 2005-05-31
Publication date: 2011-04-20
Anticipated expiration: 2025-05-31
Also published as: US7927019B2; CA2610407A1; KR101022104B1; MX2007015178A; EP2532904A3; KR100967640B1; EP2532904A2; CA2610407C; AU2005332456A1; US20090016665A1; KR20080009738A; EP1887237A1; EP1887237A4; AU2005332456B2; KR20100035186A; WO2006129351A1; CN101194110A

Abstract

A slewing ring bearing has an outer ring having a first and a second circumferential grooves parallelly formed in the inner circumferential surface of the outer ring; an inner ring provided on the inner side of the outer ring and having a first and a second circumferential grooves parallelly formed in the outer circumferential surface of the inner ring so as to correspond to the first and second circumferential grooves of the outer ring; a first rolling body row provided in the first circumferential groove of the outer ring and the first circumferential groove of the inner ring; and a second rolling body row provided in the second circumferential groove of the outer ring and the second circumferential groove of the inner ring. The inner ring rotates around a rotation axis in a relatively opposite direction to the outer ring via the first rolling body row and the second rolling body row. The slewing ring bearing has a load distribution structure as follow: in the load distribution structure, a difference between a first load distribution applied to the first rolling body row and a second load distribution applied to the second rolling body row is feasibly reduced. The load distribution structure comprises a first side plate and a second side plate connected to the outer ring or the inner ring, and the first side plate and the second side plate provide different rigidities for the outer ring or the inner ring.

Description

Rotary ring bearing structure

Technical field

The present invention relates to a kind of rotary ring bearing structure, particularly the rotary ring bearing structure of biserialization.

Background technique

Wish to utilize for the little natural energy resources of environment burden in order to preserve our planet environment.As a kind of natural energy resources, wind energy is rising.Propeller generator is to be the rotating machinery of electric energy with wind energy transformation.As shown in Figure 1, propeller generator constitutes, and comprises the supporting tower, is supported the windmill matrix 102 of tower rotation supporting freely, by the windmill matrix 102 rotations impeller matrix (rotor head) 103 of supporting freely.A plurality of wings (three wings are arranged in this embodiment) 104A, 104B, 104C are rotated (spacing can freely change) supporting freely via rotating ring bearing 105A, 105B, 105C by rotor head 103 respectively.As shown in Figure 2, rotating ring bearing 105B is formed by ring 107 in the rotation of the non-rotating outer shroud 106 of rotor head side and flank.Between outer shroud 106 and interior ring 107, be provided with the rolling element row 108 of ring-type.Have the ball or the shape of the rotation roller of cylndrical surface or sphere roughly as the rolling element of rolling element row 108 key elements.

Among the rotating ring bearing 105B of a slice wing 104B in supporting three wings shown in Figure 1, effect has following power: axially the external force Fxb of XB, around the rotating torques Mxb of this direction XB, radially YB external force Fyb, around the rotating torques Myb of this direction YB, with the external force Fzb of the radially ZB of the rotating shaft direct cross of rotor head 103, around the rotating torques Mzb of this axial ZB.Three-dimensional active force like this produces surface pressure with respect to a plurality of rolling elements of outer shroud 106, interior ring 107 and rolling element row 108.Such surface pressure acts on outer shroud 106, interior ring 107 and rolling element row 108 as the elastic deformation force.Such deformation force is as representing that corresponding to the distribution function of the circumferential locations of the ball that is arranged in a plurality of rolling elements on the same circumference number the ball load that rolling element is suffered or the surface pressure of its position are fixing, but produces big change.Such deformation force is as the former of the big friction that produces on swivel bearing 105A, 105B, 105C thereby manifest the life-span of shortening rotating ring bearing.

Be associated with above-mentioned explanation, open (Japan) spy and put down in writing the biserial swivel bearing in the 2002-13540 communique.In this conventional example, patchhole is set and rolling element is inserted at the radial direction of outer shroud or interior ring.Though record the insertion that is accompanied by roller, the precompressed amount increases gradually, does not put down in writing the precompressed amount of each row.

In addition, open in the flat 7-310645 communique (Japan) spy and disclose awe.In this conventional example, alar part can be changed the supporting of spacing ground via the rotating ring bearing by rotor head, and the rotating ring bearing supports radial load and thrust load simultaneously.This rotating ring bearing is a single row bearing.

Summary of the invention

The object of the present invention is to provide and a kind ofly can realize the biserialization of rotating ring bearing and the rotating ring bearing of surface pressure homogenization (homogenization of rolling element load) simultaneously.

Other purpose of the present invention is to provide a kind of passing through suitably to wait load distribution with rotating ring bearing biserialization and with the rolling element load distribution, thereby realizes the rotating ring bearing of surface pressure homogenization.

It is a kind of with rotating ring bearing biserialization that another other purpose of the present invention is to provide, and realizes the rotating ring bearing of surface pressure homogenization when the load unequal distribution.

Another other purpose of the present invention is to provide a kind of wind generating unit that uses above-mentioned rotating ring bearing.

According to viewpoint of the present invention, the rotating ring bearing has: outer portion, and it has first and second circumferential grooves that are formed on inner peripheral surface abreast; Internal ring portion, the inboard that it is arranged at described outer portion, it is corresponding and be formed on first and second circumferential grooves of outer circumferential face abreast to have described first and second circumferential grooves with described outer portion; First rolling element row, it is arranged at described first circumferential groove of described outer portion and described first circumferential groove of described internal ring portion; Second rolling element row, it is arranged at described second circumferential groove of described outer portion and described second circumferential groove of described internal ring portion.Via described first rolling element row and described second rolling element row, described internal ring portion is around the axial rotary direction rotation opposite with respect to described outer portion.

At this, be preferably, first precompression of the rolling element of corresponding with described first peripheral part described first rolling element row is bigger than second precompression of the rolling element of the described second rolling element row corresponding with described second peripheral part.

At this moment, also the thickness of the described second peripheral part radial direction of comparable described outer portion is thick for the thickness of the described first peripheral part radial direction of described outer portion.In addition, second diameter of the rolling element radial direction of also comparable described second rolling element row of first diameter of the rolling element radial direction of described first rolling element row is little.

In addition, the axial width of described rotation that both can be described outer portion equates that with the axial width of described rotation of described internal ring portion the axial width of described rotation that also can be described outer portion is bigger than the axial width of described rotation of described internal ring portion.

When the axial width of described rotation of described outer portion was bigger than the axial width of described rotation of described internal ring portion, described outer portion also can further have the side plate that combines with the face of the described outer portion of described running shaft direction quadrature.On this basis, described internal ring portion also can further have the side plate that combines with the face of the described outer portion of described running shaft direction quadrature.

In addition, the rolling element of described first and second rolling elements row both can be ball, also can be roller.

In addition, in other viewpoint of the present invention, wind generating unit has: export the rotor head that is connected with running shaft with wind-force; A plurality of wings; The described rotating ring bearing that is provided with for described a plurality of wings are combined with described rotor head respectively.

Description of drawings

Fig. 1 is the stereogram of the known rotary ring bearing structure of expression;

Fig. 2 is the stereogram of the known rotating ring bearing of expression;

Fig. 3 is the stereogram of the rotary ring bearing structure of expression applicable object of the present invention;

Fig. 4 is the sectional axonometric drawing of Fig. 3 part;

Fig. 5 is the sectional drawing of the region division of expression rotating ring bearing;

Fig. 6 is the sectional drawing of expression windmill of the present invention with the embodiment of rotary ring bearing structure;

Fig. 7 is the sectional drawing of expression windmill of the present invention with other embodiment of rotary ring bearing structure;

Fig. 8 is the sectional drawing of expression windmill of the present invention with other embodiment of rotary ring bearing structure;

Fig. 9 is the sectional drawing of expression windmill of the present invention with other embodiment of rotary ring bearing structure;

Figure 10 is the sectional drawing of expression windmill of the present invention with other embodiment of rotary ring bearing structure;

Figure 11 is the figure of expression windmill of the present invention with the ball load distribution of rotary ring bearing structure;

Figure 12 is the figure of expression windmill of the present invention with other ball load distribution of rotary ring bearing structure;

Figure 13 is the figure of expression windmill of the present invention with the surface pressure distribution of rotary ring bearing structure;

Figure 14 is the figure of expression windmill of the present invention with other surface pressure distribution of rotary ring bearing structure;

Figure 15 is the figure of expression windmill of the present invention with other ball load distribution of rotary ring bearing structure;

Figure 16 is the figure of expression windmill of the present invention with other ball load distribution of rotary ring bearing structure;

Figure 17 is the figure of expression windmill of the present invention with other surface pressure distribution of rotary ring bearing structure;

Figure 18 is the figure of expression windmill of the present invention with other surface pressure distribution of rotary ring bearing structure.

Embodiment

Below, explain rotating ring bearing of the present invention with reference to accompanying drawing.Though is example explanation rotating ring bearing with windmill with the rotating ring bearing, self-evident for a person skilled in the art, the present invention goes for general rotating ring bearing.

Fig. 3 is the stereogram of the windmill of expression first embodiment of the invention with rotary ring bearing structure.With reference to Fig. 3, impeller body (rotor head) 1 is provided with wind-force output running shaft 2 and three groups of rotating ring bearings 3.Three wings (not shown) that can change spacing are respectively by 3 supportings of three groups of rotating ring bearings.Three groups of rotating ring bearings 3 running shaft separately with the 120 equal angles arranged spaced of spending at grade.

In Fig. 4, rotating ring bearing 3 is formed by outer shroud 4 that is fixed on rotor head 1 and the interior ring 5 that is fixed on the wing.Between the outer circumferential face of the inner peripheral surface of outer shroud 4 and interior ring 5, be provided with the first rolling element row 6 and the second rolling element row 7.The first rolling element row 6 and the second rolling element row 7 rolling element separately have ball or the such shape of roller.The first rolling element row 6 and the second rolling element row 7 axially separating at running shaft L with interval D.

Analyze implementing FEM (finite element method) at the surface pressure of outer shroud 4 and the 5 surface generations of interior ring, its result retouches line and represents on this surface.Keep the first rolling element row 6 and the second rolling element row 7 separately the guard ring of rolling element (retainer) may be separately formed, or integrally formed with outer shroud 4 or interior ring 5.As the first rolling element row 6 and the second rolling element row 7, can utilize ball, sphere roller.

Load distribution such as Fig. 5 represents to pass through or do not wait load distribution, load f1 and load f2 are assigned with in the running shaft direction, and the surface pressure of circumferencial direction is by two zones of homogenization (with the planarization of surface pressure difference cloth).The coordinate of circumferencial direction uses ball that the ball to a plurality of rolling elements of arranging on the same circumference distributes number to represent.Therefore, the coordinate of circumferencial direction is by discretization.On the running shaft direction, outer shroud 4 imaginations that form as one are divided into first outer portion 8 corresponding with the first rolling element row 6 and second outer portion 9 corresponding with the second rolling element row 7.On the running shaft direction, interior ring 5 imaginations that form as one are divided into first internal ring portion 11 corresponding with the first rolling element row 6 and second internal ring portion 12 corresponding with the second rolling element row 7.First outer portion 8 and second outer portion 9 are divided in the running shaft direction by the imaginary median plane S with running shaft L-orthogonal.First internal ring portion 11 and second internal ring portion 12 are divided in the running shaft direction by imaginary median plane S.

Fig. 6 represents the example of the load distribution of the windmill usefulness rotary ring bearing structure that the present invention is suitable for.The load f1 that acts on first outer portion, 8 outside circumference was preferably than load f2 hour that acts on second outer portion, 9 outside circumference, and the ball diameter of the first rolling element row 6 is littler than the ball diameter of the second rolling element row 7.Because of the load-carrying load carrying capacity of the big more then ball of ball diameter is big more, therefore, in this embodiment, the degree of deformation or the internal stress distribution of first outer portion 8 and second outer portion 9 can homogenizations.

Fig. 7 represents other example of the load distribution of the windmill usefulness rotating ring gear mechanism that the present invention is suitable for.In this embodiment, the ball diameter of the first rolling element row 6 and the second rolling element row 7 equates.Act on the load f1 of first outer portion, 8 outside circumference when bigger than the load f2 that acts on second outer portion, 9 outside circumference, for the rigidity that makes first outer portion 8 is bigger than the rigidity of second outer portion 9, the thickness of the radial direction of first outer portion 8 thickens to thicker than the radial direction thickness of second outer portion 9.Its result, load act on the big side of rigidity more, thus realize the first rolling element row 6 and the second rolling element row 7 load etc. distribution.Load distribution such as pass through, the surface pressure of bearing (surface pressure difference cloth) is by homogenization.Such magnitude relationship of first outer portion 8 and second outer portion 9 is correct as the generality tendency.But in fact the result who analyzes based on the FEM to practical structures determines the axial position of rotation of its thickness, shape, imaginary centres face S.In this embodiment, load distribution such as can realize.

Fig. 8 represents the other example of the load distribution of the windmill usefulness rotating ring gear mechanism that the present invention is suitable for.In this embodiment, the embodiment with Fig. 7 is identical on the shape this point of adjusting outer shroud 4 and interior ring 5.The magnitude relationship of corresponding f1 and f2 is determined the magnitude relationship of the axial width of rotation of outer shroud 4 and interior ring 5.In addition, determine the magnitude relationship of the axial width of rotation of first outer portion 8 and second outer portion 9 or the magnitude relationship of the running shaft direction width of first internal ring portion 11 and second internal ring portion 12 based on the magnitude relationship of f1 and f2.In this embodiment, load distribution such as can realize.

Fig. 9 represents other example of the load distribution of the windmill usefulness rotating ring gear mechanism that the present invention is suitable for.Based on the magnitude relationship of f1 and f2, to the ball diameter D1 of the first rolling element row 6 and the very little poor Δ D of ball diameter D2 assignment of the second rolling element row 7.

Δ D=D2-D1=K* (f2-f1) K: small constant

Be provided with the first rolling element row 6 and the second rolling element row, 7, the first rolling element row 6 and the second rolling element row 7 between outer shroud 4 and the interior ring 5 by outer shroud 4 and the 5 firmly clampings of interior ring.At this moment, act on the load f1 of first outer portion, 8 outside circumference when bigger, because of big slightly ball 7 one sides' of ball diameter precompression is big, so it is big that the rigidity of ball 7 becomes than the load f2 that acts on second outer portion, 9 outside circumference.Its result, load act on the big side of rigidity more, thus realize the first rolling element row 6 and the second rolling element row 7 load etc. distribution.In this embodiment, by regulating ball diameter and adjusting precompression, can be with the surface pressure homogenization of bearing, the planarization of surface pressure difference cloth.Idea according to the adjustment precompression of this example, though it is not shown, but very little poor by between the diameter D2 ' of the outer shroud of the diameter D1 ' of the outer shroud of the first rolling element row 6 and the second rolling element row 7, being provided with, thus can two be listed as between with the surface pressure distribution homogenization (planarization) of bearing.

Other example of load distribution such as Figure 10 represents.Determine that based on f1 and f2 magnitude relationship the ring flat-plate (side plate) 13 of thickness is installed on the lateral circle surface of first outer portion 8, determine that based on f1 and f2 magnitude relationship the ring flat-plate (side plate) 13 of thickness is installed on the lateral circle surface of second outer portion 9.In addition, determine that based on f1 and f2 magnitude relationship the ring flat-plate 13 ' of thickness is installed on the lateral circle surface of first internal ring portion 11, determine that based on f1 and f2 magnitude relationship the ring flat-plate 13 ' of thickness is installed on the lateral circle surface of second internal ring portion 12.The thickness that is installed on the ring flat-plate 13 of first outer portion 8 also can be adjusted based on the magnitude relationship of f1 and f2 with the thickness that is installed on the ring flat-plate 13 ' of first internal ring portion 11.The thickness that is installed on the ring flat-plate 13 of second outer portion 9 also can be adjusted based on the magnitude relationship of f1 and f2 with the thickness that is installed on the ring flat-plate 13 ' of second internal ring portion 12.Thereby by load distribution such as the rigidity adjustment can realize.

In addition, above-mentioned ring flat-plate also can only be arranged at outer portion 4, or only is arranged at internal ring portion 5.This ring flat-plate also can be with near the hands-off mode of the running shaft that internal ring portion 5 combines extends to running shaft always.

Figure 11～Figure 14 represents the FEM analysis result of the load that is assigned with by above-mentioned load distribution.At this, transverse axis is around the inside and outside ring angle coordinate in one week, by the ball discretization.The apportionment ratio that Figure 11 represents to change f1 and f2 carries out the rolling element load distribution of FEM rotor head side when analyzing.The ball load of the ball load ratio flank of rotor head side is big.Ball load distribution when loading the normal load of apportionment ratio 50%, the ball load distribution during with the load that loads apportionment ratio 59% or apportionment ratio 61% is compared, and is suppressed for a short time in the whole circumference zone in the rotor head side.Figure 13 represents the surface pressure distribution of the rotor head side corresponding with ball load distribution shown in Figure 11.Surface pressure distribution when loading the load of apportionment ratio 50%, the surface pressure distribution during with the normal load that loads apportionment ratio 59% or apportionment ratio 61% is compared, and is suppressed for a short time in the whole circumference zone in the rotor head side.Like this, in ball load distribution and the big side of surface pressure distribution, their value is suppressed for a short time, and in ball load distribution and the little side of surface pressure distribution, it is big that their value becomes, and two kinds of distributions are flattened.Figure 12 and Figure 14 represent that two row ball load difference cloth and surface pressure difference cloth are flattened, and wait distribution suitably to distribute.

The FEM analysis result of load when Figure 15～Figure 18 represents additional ring flat-plate (side plate) shown in Figure 10 13,13 '.The expression apportionment ratio is close 50% 48% o'clock, and in ball load and the big rotor head side of surface pressure, its ball load difference cloth and surface pressure difference cloth further are flattened on the whole.

(second embodiment)

As other example that does not wait load distribution, use biserial sphere roller bearing, regulate precompression by pair roller, the load-carrying ability of bearing rises, and it is unequal to absorb some load.The retainer of the retainer of the first rolling element row 6 and the second rolling element row 7 is integrated, help the homogenization (planarization) of surface pressure.Can be effectively with the ball load homogenization on the circumference.For with this ball load homogenization, the rolling surface of outer shroud 4 and the rolling surface of interior ring 5 are formed non-positive circle in the lump, or with the square Cheng Feizheng circle in outer shroud 4 and the interior ring 5, by adjusting the precompression that this ball is applied, can be with the surface pressure distribution homogenization (planarization) of bearing.

As mentioned above, according to biserial rotating ring bearing of the present invention, by the planarization of load difference cloth with the planarization of surface pressure difference cloth, thereby can realize the biserialization and the homogenization of surface pressure difference of rotating ring bearing simultaneously.Thus, corresponding biserial rolling element row, the load that outer shroud and interior ring are shared can be assigned with equably.Etc. load distribution can be that the longitudinal rigidity (bearing rigidity+supporting rigidity) that high rigidity or corresponding each rolling element are listed as equates to realize by biserial rotating ring bearing.

Claims

1. rotating ring bearing is characterized in that having:

Outer shroud, it has first and second circumferential grooves that are formed on inner peripheral surface abreast;

In ring, the inboard that it is arranged at described outer shroud, it is corresponding and be formed on first and second circumferential grooves of outer circumferential face abreast to have described first and second circumferential grooves with described outer shroud;

First rolling element row, it is arranged at described first circumferential groove of described outer shroud and described first circumferential groove of described interior ring;

Second rolling element row, it is arranged at described second circumferential groove of described outer shroud and described second circumferential groove of described interior ring,

Via described first rolling element row and described second rolling element row, described interior around the axial rotary circumferencial direction rotation opposite with respect to described outer shroud,

Described rotating ring bearing has following load distribution structure, in this load distribution structure, first load distribution that puts on first rolling element row and the difference that puts between second load distribution that second rolling element is listed as is reduced effectively,

Wherein said outer shroud comprises:

Have described outer shroud described first circumferential groove first outer portion and

Second outer portion with described second circumferential groove of described outer shroud,

Described load distribution structure comprises respectively first side plate and second side plate that is connected with second outer portion with described first outer portion,

Described first side plate provides different rigidity to described first outer portion with second outer portion with second side plate.

2. rotating ring bearing as claimed in claim 1 is characterized in that, the rolling element of described first and second rolling elements row is balls.

3. rotating ring bearing as claimed in claim 1 is characterized in that, the rolling element of described first and second rolling elements row is rollers.

4. rotating ring bearing is characterized in that having:

Ring comprises in wherein said:

Have described in the ring described first circumferential groove first internal ring portion and

Second internal ring portion with described second circumferential groove of described interior ring,

Described load distribution structure comprises respectively first side plate and second side plate that is connected with second internal ring portion with described first internal ring portion,

Described first side plate provides different rigidity to described first internal ring portion with second internal ring portion with second side plate.

5. rotating ring bearing as claimed in claim 4 is characterized in that, the rolling element of described first and second rolling elements row is balls.

6. rotating ring bearing as claimed in claim 4 is characterized in that, the rolling element of described first and second rolling elements row is rollers.

7. wind generating unit, it has:

Export the rotor head that is connected with running shaft with wind-force;

A plurality of wings;

The rotating ring bearing that is provided with for described a plurality of wings are combined with described rotor head respectively,

Wherein, described rotating ring bearing has:

Wherein said outer shroud comprises:

8. wind generating unit as claimed in claim 7 is characterized in that, the rolling element of described first and second rolling elements row is balls.

9. wind generating unit as claimed in claim 7 is characterized in that, the rolling element of described first and second rolling elements row is rollers.

10. wind generating unit, it has:

Export the rotor head that is connected with running shaft with wind-force;

A plurality of wings;

Wherein, described rotating ring bearing has:

Ring comprises in wherein said:

11. wind generating unit as claimed in claim 10 is characterized in that, the rolling element of described first and second rolling elements row is balls.

12. wind generating unit as claimed in claim 10 is characterized in that, the rolling element of described first and second rolling elements row is rollers.